Restoration of colony-forming activity in osmotically stressed Escherichia coli by betaine.

Exposure of Escherichia coli to 0.8 M NaCl caused a rapid and large decrease in colony-forming activity. When such osmotically upshocked cells were exposed to betaine, colony-forming activity was restored. Betaine was able to restore colony-forming activity even when chloramphenicol inhibited protein synthesis. Thus, restoration was not the result of cell turnover. The cells were not killed by exposure to 0.8 M NaCl, because during exposure they accumulated ATP intracellularly. Betaine treatment caused this cellular ATP to decrease to a lower level. This work may provide the foundation for a simple plating procedure to quantitatively detect nonculturable E. coli in ocean beach recreational waters.

Independence of cyclic AMP and relA gene stimulation of glycogen synthesis in intact Escherichia coli cells.

Previous studies from our laboratory established that in Escherichia coli, glycogen synthesis is regulated by both the relA gene, which mediates the stringent response, and by cyclic AMP. However, those studies raised the question of whether this dual regulatory system functions in an independent or a dependent manner. We show here that this regulation is independent, i.e., each regulatory process can express its action in the absence of the other. Triggering the stringent response by amino acid starvation increased glycogen synthesis even in mutants lacking the ability to synthesize cyclic AMP or lacking cyclic AMP receptor protein; and cyclic AMP addition stimulated glycogen synthesis in relA mutant strains. We also show that physiological concentrations of GTP inhibit ADP-glucose synthetase (glucose-1-phosphate adenylyltransferase, EC 2.7.7.27), the rate-limiting enzyme of bacterial glycogen synthesis, in vitro. Because the stringent response is known to cause an abrupt decrease in the cellular level of GTP, modulation of ADP-glucose synthetase activity by this nucleotide could account for a substantial portion of the step-up in the cellular rate of glycogen synthesis observed when the stringent response is triggered.

Osmotic stress drastically inhibits active transport of carbohydrates by Escherichia coli.

In intact Escherichia coli cells, severe osmotic stress almost totally inhibited active transport of carbohydrate by all of the systems known to transport carbohydrates in E. coli: group translocation (glucose), binding-protein mediated transport (maltose), proton symport (lactose), and sodium cotransport (melibiose). Detailed study of glucose transport showed that this inhibition of transport was not secondary to the inhibition of growth by osmotic stress, but rather that the inhibition of transport of a source of carbon and energy was sufficient to cause the complete inhibition of growth observed during severe osmotic upshock. Transport and growth inhibition did not result from cell death; upshocked cells were viable and metabolically active.

Restoration of cell volume and the reversal of carbohydrate transport and growth inhibition of osmotically upshocked Escherichia coli.

Resumption of growth in osmotically upshocked Escherichia coli was effected only by an external stimulus (betaine treatment) in severe upshock, but was spontaneous in less severe upshock. In either case, growth resumption was preceded by a reversal of glucose transport inhibition, and that reversal was preceded by a recovery of cell volume. We hypothesize that deformation of the membrane by osmotic stress results in conversion of a membrane component of the transport system to a less functional conformation, which results in the inhibition of transport and the consequent inhibition of growth. Relief of the deformation would then allow recovery to a more functional conformation, reversal of transport inhibition, and then resumption of growth.

Evidence that cyclic AMP stimulates bacterial glycogen synthesis by relieving AMP inhibition of and by increasing the cellular level of ADP-glucose synthetase.

Using Escherichia coli mutants that possess an ADP-glucose synthetase (EC 2.7.7.27, the rate-limiting enzyme of bacterial glycogen synthesis) that differs in its inhibition by physiological levels of AMP, evidence was obtained that cyclic AMP stimulates cellular glycogen synthesis during nitrogen starvation by relieving AMP inhibition of this enzyme (without altering the cellular AMP level). Deinhibition for AMP of an enzyme controlled by the adenylate energy charge allows selective release from this control despite the maintenance of a constant cellular energy charge value. It was also shown that an additional increase in rate, not accounted for by AMP deinhibition, was due to an increase in the cellular level of ADP-glucose synthetase.

Identification of GTP as a physiologically relevant inhibitor of Escherichia coli ADP-glucose synthetase.

We show that physiological concentrations of GTP can significantly inhibit wild-type Escherichia coli ADP-glucose synthetase (the rate-limiting enzyme of bacterial glycogen synthesis) and that mutant-strain enzymes known to show less inhibition by physiological AMP levels also show less inhibition by physiological levels of GTP. This decreased inhibition by both AMP and GTP can almost totally account for the higher cellular rates of glycogen synthesis observed in the mutant strains. In addition, in metabolic conditions where we have shown that cellular glycogen synthesis increases, cellular GTP levels are known to decrease. Thus, we conclude that GTP inhibition is physiologically relevant.